Conformation of hydrogen-bonded dimeric o-methyl-substituted benzoic acids

2,4-Dimethylbenzoic acid, (I), was obtained by the acetylation of m-xylene by acetic acid in the presence of P₂O₅ as catalyst. According to Kosolapoff (1947), in the course of this reaction mono- and diacetyl derivatives of m-xylene form, and the latter is found in the high-boiling fraction. Our studies reveal that the compound is actually 2,4-dimethylbenzoic acid, (I).

Molecules of (I) crystallize in the form of centrosymmetric hydrogen-bonded dimers. One such dimer is presented in Fig. 1, with the atom-numbering scheme. The carboxyl group in (I) shows C—O bond-length alteration, with distances of 1.3085 (19) and 1.2251 (18) Å. The relevant C—C—O angles are also different, at 114.34 (14) and 124.02 (14)°. The differences between these bond lengths (Δd) and angles (Δϕ) obey the relation given by Borthwick (1980), i.e. Δϕ = -100 × Δd (ϕ in degrees, d in Å). The carboxyl group is twisted with respect to the phenyl ring. The dihedral angle between the plane of the phenyl ring and the plane of atoms O1, O2, C1 is 14.06 (3)°. The methyl group in the ortho-position is splayed away from the carboxyl group and this is illustrated by the different values of the angles C2—C3—C8 and C4—C3—C8, which are 124.23 (14) and 118.57 (14)°, respectively. In contrast, the angles C4—C5—C9 and C6—C5—C9 are nearly equal and the methyl group in the para position is located symmetrically.

The centrosymetric hydrogen-bonded dimer of (I) is described using the common motif which occurs in most other monocarboxylic acids (Leiserowitz, 1976), namely R²₂(8) (Etter, 1990) (Fig. 1). The H1··· O2ⁱ and O1···O2ⁱ distances are 1.71 (3) and 2.646 (2) Å, respectively [symmetry code: (i) -x, -y, 1 - z]. The O1—H1···O2ⁱ angle is 176 (3)°. The molecular packing of (I) is best described as comprising puckered sheets of carboxylic acid hydrogen-bonded dimers but there are no significant interactions between dimers.

The observed in-plane splaying and the non-coplanarity of the carboxyl group and the phenyl ring of (I) indicate that the molecular conformation is influenced by the presence of a methyl group in the ortho-position. In other methylbenzoic acid derivatives, it was found that there are two ways in which the steric strain caused by the closeness of a carboxyl and a methyl group can be relieved (Barcon et al., 1997). First of all, the carboxyl and the o-methyl groups exhibit evasive in-plane splaying, Δ. This parameter was calculated by adding the values of the C2—C3—C8 and C4—C3—C8 angles and subtracting 240° from the sum. The second possibility for relieving steric strain is a twist of the carboxyl group around the C_benz—C_carboxyl bond. To examine these parameters for benzoic acid derivatives, we performed a search of the Cambridge Structural Database (CSD, Version 5.28, August 2007; Allen, 2002; Bruno et al., 2002). The following restrictions were made: R < 10%, at least one methyl group present in an ortho-position, and the remaining substituents restricted to be only H, methyl, Cl or Br. Moreover, only acids forming hydrogen-bonded dimeric structures were taken into account. In the case of two acids, namely 2-methylbenzoic acid (Byrn et al., 1993) and 2,4,6-trimethylbenzoic acid (Gdaniec et al., 2003), structural data for the acid molecules acting as guest molecules or found in cocrystals were also included. This provided us with a set of 14 molecules. The angle of twist and the angle for combined in-plane splay have been calculated for (I) and all the structures obtained from the CSD search. In the case of acids with methyl groups in both ortho-positions, the in-plane splay was taken as the mean of the two values.

The scatter graph (Fig. 2) shows the relation between the twist of the carboxyl group and the in-plane splay. The data are separated into three clusters. The points at the bottom right-hand corner correspond to the structures of mono-ortho-substituted acids. The value of Δ ranges from 5.6 to 7.1°, whereas that of the twist angle ranges from 1.0 to 14.1°. The parameters of the benzoic acid derivatives with a methyl group in both ortho-positions and with both meta-positions vacant lie in the middle cluster. In this cluster, the values of Δ and the twist fall in the ranges 2.4–4.0° and 32.6–51.6°, respectively. It should be noted that for pure 2,4,6-trimethylbenzoic acid measured at 100 K (Wilson & Goeta, 2004), the values of Δ and the twist angle are 2.9 and 42.7°, respectively. When the same compound forms a cocrystal with 1,4-bis(pentafluorophenyl)butadiyne (Gdaniec et al., 2003), these values change to 4.0 and 32.6°, respectively. Moreover, the data provided by Wilson & Goeta (2004) for pure 2,4,6-trimethylbenzoic acid measured at different temperatures in the range 100–290 K show small changes of the parameters in question. At the top left-hand corner of Fig. 2 there is a cluster of points, which corresponds to the pentasubstituted acids. The buttressing effect (Westheimer, 1956) of the substituents in the meta-position hinders the in-plane splaying but a twist angle of approximately 90° is observed.

Summarizing, the observed relationship shows that the in-plane splaying and the twist angle of the carboxyl group are interdependent parameters with a correlation factor of 0.98 (4). Steric strains introduced by substituents in the ortho-position are primarily released by in-plane splaying. However, if the buttressing effect of groups in the meta-positions occurs, in-plane splaying is unfavourable. Thus, the twist of the carboxyl group becomes significant and approaches 90° with a loss of resonance stabilization. The structures of 2,4,6-trimethylbenzoic acid molecules in various molecular environments are good examples of the fact that the molecular conformation is also to some extent dependent on other factors, such as crystal packing forces and weak intermolecular interactions.